KR0136160Y1 - Hydraulic pressure intensifier - Google Patents

Abstract

The present invention relates to a hydraulic booster in a hydraulic system, and in particular, since the hydraulic pump and the hydraulic motor are mechanically connected, a certain pressure is raised to the high pressure of a specific pressure required by the system without the aid of power or power unlike a general pump. (E.g., about 1,600 psi to about 3,000 psi). The main configuration of the present invention, the manifold (40) having an inlet (41); A hydraulic motor unit 10 for converting the flow rate and the hydraulic pressure from the inlet port 41 into rotational force; A power transmission unit 30 for transmitting the rotational force of the hydraulic motor unit 10, and a hydraulic pump unit 20 for converting the rotational force of the power transmission unit 30 into hydraulic pressure and flow rate; Characterized in that the manifold 50 having an outlet 52 for discharging the hydraulic pressure and flow rate of the hydraulic pump unit 20.

Description

Hydraulic booster

1 is a cross-sectional view of the hydraulic booster according to the present invention.

* Explanation of symbols for main parts of the drawings

10: hydraulic motor unit 11: motor drive shaft

12 piston 13 cylinder block

14: Spline 15: Shoo

16: shoe fixing plate 17: wear plate

19: valve plate 21: pump drive shaft

29 valve plate 30 power transmission unit

40: manifold 41: hydraulic port

50: manifold 52: outlet

The present invention relates to a hydraulic booster in a hydraulic system. More specifically, unlike a general pump, it is possible to raise a certain pressure to a high pressure of a specific pressure required by the system without the aid of power or power (for example, about 1,600 psi to about 3,000 psi) booster.

In general, in the case of a conventional fixed displacement piston type hydraulic pump, power is generated by an electric motor, and the hydraulic pump is driven by this power. In other words, the power generating part is made of an electric motor, and the hydraulic generating part is composed of two structural systems each made of a hydraulic motor.

However, when the hydraulic system itself is not fixed but mobile, DC power must be used. Therefore, in case of DC motor, the overload protection device should be installed in the DC motor because the rotation speed changes according to the change of the hydraulic pump load, that is, the discharge port quantity. .

In addition, in the case of continuous operation for a certain period of time, rather than intermittent operation, the battery must be set in consideration of power consumption of the DC motor, and there is a disadvantage in that a large capacity is required.

In addition, since the cooling system for cooling the DC motor itself is installed, the volume of the entire hydraulic boosting device is also increased.

The present invention solves the conventional problems as described above, and its purpose is advantageous for using some high pressure in a mobile hydraulic system, and particularly suitable for use in a narrow place and difficult power supply, such as a tank To provide a hydraulic booster for use in maneuvering equipment.

In order to achieve the object of the present invention as described above, the hydraulic boosting device of the present invention,

A manifold having an inlet; A valve plate receiving the hydraulic pressure is formed so as to be rotated by the hydraulic pressure introduced from the inlet, a rotating means is formed so as to convert the pressing force of the valve plate into the rotating force, and a motor drive shaft is formed to axially rotate under the rotational force of the rotating means, and the rotating force of the motor shaft. A hydraulic motor having a spline formed to transmit the power to the power transmission unit; A power transmission unit for transmitting the rotational force of the hydraulic motor; A hydraulic pump for converting rotational force of the power transmission unit into hydraulic pressure and flow rate; It consists of a manifold with an outlet for discharging the hydraulic pressure and the flow rate of the hydraulic pump.

In addition, the rotating means is characterized by consisting of a piston, a shoe and wear plate coupled to the piston tip, a cam plate inclined contact with the wear plate, and a cylinder block installed on the outer periphery of the piston and rotated by the piston.

Hereinafter, with reference to the accompanying drawings the configuration of the present invention will be described in detail as follows.

1 is an internal cross-sectional view of the hydraulic booster according to the present invention, the hydraulic booster according to the present invention is largely the hydraulic motor unit 10, the hydraulic pump unit 20, and the power transmission unit (30). It is composed.

The hydraulic motor unit 10 and the hydraulic pump unit 20 are substantially the same in configuration except for some components.

In the hydraulic motor unit 10 and the hydraulic pump unit 20, a plurality of pistons 12 (for example, nine) are arranged side by side as axes parallel to the outer circumference with respect to the motor drive shaft 11. The configuration of the hydraulic pump unit 20 and the hydraulic motor unit 10 having the same configuration is only described in one configuration, and the detailed description of the other configuration is omitted.The piston 12 is a cylinder formed on its outer periphery. Reciprocating motion is performed in block 13.

In addition, the cylinder block 13 is connected to the motor drive shaft 11 toward the inner circumference and a spline 14 is formed at the tip of the motor drive shaft to transmit rotational power to the power transmission unit 30.

The tip of the piston 12 is formed into a spherical surface, which is in the form of engaging with the shoe 15 as shown.

The shoe 15 is supported toward the cam plate 18 by the shoe fixing plate 16 and the wear plate 17.

An operation relationship according to the above basic configuration will be described below.

First, when the flow rate and the input are supplied through the inlet 41 of the manifold 40, the hydraulic pressure acts on the valve plate 19 and the cylinder block 13, so that the diameter of the tip of the piston 12 in the cylinder block 13 is reduced. Force is applied to the surface of the photographic shoe 15. Then, a part of the reaction force is acted vertically on the side of the piston 12 so that when the piston 12 is inclined, torque is generated in the axial direction in the cylinder block 13 so that the cylinder block 13 is rotated.

Since this is the same as the basic operating principle of a general piston motor, a detailed and detailed description of the operating principle of the force is omitted.

Subsequently, the motor drive shaft 11, the spline 14, and the power transmission unit 30 connected to the cylinder block 13 rotate to transmit rotational power to the hydraulic pump unit 20.

As the power transmission unit 30 rotates, the pump drive shaft 21 rotates, and the cylinder block 23 rotates in the reverse order of the power transmission process of the hydraulic motor unit 10 described above, and the piston 22 rotates. .

As the piston 22 rotates, the valve plate 29 is pressurized in the reverse order of operation principle of the same force as that of the piston 12 of the hydraulic motor 10 to generate pressure and flow rate toward the outlet 52 of the pump. Is sent.

Although not specifically shown in the drawings, the internal leakage of the motor is configured to be discharged to the case drain port of the pump by connecting to the tube.

According to the actual measurement, for example, when the pressure at the motor inlet was 1,600pis and the flow rate was 72 1 / min, the pressure at the pump outlet was 2,600 to 3200 psi and the flow was 25 to 34 1 / min. .

In case of generating power by using electric motor, input voltage and current are needed and separate cooling device is required.If the system itself is a mobile device instead of a fixed type, DC power should be used. The power must be increased.

In addition, space should be reserved for the installation of suitable cooling systems.

However, when connected in the configuration of the hydraulic motor unit and the hydraulic pump unit as in the present invention can be boosted from low pressure to high pressure only by the hydraulic pressure without the need for a separate external power, which is particularly applicable to the mobile system, some places where power is not supplied, Regardless of location, it can be used even in narrow places.

In addition, since the hydraulic motor unit 10 and the hydraulic pump unit 20 are directly connected in structure, the structure thereof is also miniaturized, and the cooling device performs a separate self-cooling because the cooling device performs cooling in the overall oil cooling device of the hydraulic system related thereto. The advantage is that it does not require a chiller for it.

In addition, the hydraulic motor unit 10 and the hydraulic pump unit 20, such as the overall mechanical coupling structure, there is an advantage that easy disassembly, assembly and repair.

Claims (3)

A hydraulic booster using a hydraulic motor device, comprising: a manifold (40) having an inlet (41); A valve plate 19 for receiving hydraulic pressure is formed so as to be rotated by the hydraulic pressure introduced from the inlet 41, and a rotation means is formed to convert the pressing force of the valve plate 19 to the rotational force, and is rotated by the rotational force of the rotation means. A hydraulic motor 10 having a spline 14 formed to transmit the rotational force of the motor shaft 11 to the power transmission unit 30 so that the motor driving shaft 11 is formed; A power transmission unit 30 for transmitting the rotational force of the hydraulic motor unit 10; A hydraulic pump 20 for converting rotational force of the power transmission unit 30 into hydraulic pressure and flow rate; A hydraulic booster, comprising a manifold (50) having an outlet (52) for discharging the hydraulic pressure and the flow rate of the hydraulic pump (20). 2. The rotating means according to claim 1, wherein the rotating means includes a piston (12), a shoe (15) and a wear plate (17) engaged with the tip of the piston (12), a cam plate (18) inclined contact with the wear plate (17), Hydraulic lifting device, characterized in that consisting of a cylinder block (13) installed on the outer periphery of the piston (12) by the piston (12). The hydraulic booster of claim 1, wherein the hydraulic pump unit (20) is symmetrically formed in the same configuration as that of the hydraulic motor unit (10).